JP2007151353A - Cassette coil and rotating electric machine equipped therewith - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cassette coil capable of ensuring sufficient insulating property at start portion of winding and periphery of coil even in the case that a high voltage is applied, improving productivity of cassette coils by reducing workload, and reducing the weight; and to propose a rotating electric machine using the same. <P>SOLUTION: A cassette coil has an insulator bobbin 10 including a cylinder assembly 14 forming a coil by winding a winding 13 with an insulating film, a wall notch 12 obtained by notching a wall in the side surface of a flange 15, out of a pair of plate-shaped flanges (15, 16) consisting of a flange 15 and a flange 16 provided at the both ends of the cylinder assembly 14. An insulating wall 11 is arranged between a start portion 13a of a winding 13 serving as one end of a coil, and a periphery of coil 13b of the winding 13 located at the flange 15 side serving as a flange of winding of the coil. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a cassette coil mounted on a stator of a rotating electric machine and a rotating electric machine using the same, and particularly, in a coil winding wound around an insulator bobbin constituting the cassette coil, the coil coil is positioned at the beginning of the coil. The present invention relates to a cassette coil having an insulating member that insulates a portion to be located and a portion located on the outer periphery of the coil, and a rotating electrical machine using the same.

  As a first prior art, a perspective view of a coil bobbin 101 disclosed in Patent Document 1 is shown in FIG. The coil bobbin 101 includes a cylindrical body 114 that forms a coil by winding a winding, and flanges 115 provided at both ends of the cylindrical body 114. A coil is formed on the insulator bobbin 101 by concentrated winding, and is mounted on a stator (not shown).

As a second conventional technique, there is a cassette coil 201 as shown in FIGS. FIG. 13 is a front view of the cassette coil 201, and FIG. 14 is a view seen from the back side of the flange 215 with the flange 216 described later omitted. As shown in FIGS. 13 and 14, the cassette coil 201 includes an insulator bobbin 210 for forming a coil. The insulator bobbin 210 includes a cylindrical body 214 around which a coil 213 is wound to form a coil, and a pair of flat plate-shaped flange portions (215, 216) provided at both ends of the cylindrical body 214. A cutout 212 is formed in the flange 215 located on one end side of the cylindrical body 214. Therefore, FIGS. 13 and 14 show a state where a coil is formed by winding the winding 213 around such an insulator bobbin 201.
Japanese Patent Laid-Open No. 11-122855 (paragraph 0017, FIG. 2)

  However, the cassette coil 201 of the second prior art has the following problems. Here, a method of forming a coil by winding the winding 213 around the insulator bobbin 210 will be described first. First, the winding 213 is inserted from the opening side of the cutout portion 212. The winding 213 is wound around the cylindrical body 214 while gradually shifting the winding 213 from the flange 215 side to the flange 216. Note that the two windings 213 are wound together. Next, the second layer winding 213 is wound around the cylindrical body 214 while the winding 213 is shifted in the reverse direction from the flange 216 side to the flange 215. Next, the third layer winding 213 is wound around the cylindrical body 214 while shifting the winding 213 again from the flange 215 side to the flange 216. In this manner, a coil having a predetermined number of layers is formed by overlapping the layer of the winding 213 on the cylindrical body 214, and the winding 213 is connected to the flange portion 216 in the uppermost layer corresponding to the outer peripheral portion of the coil. The winding 213 is shifted from the side to the flange portion 215, and the winding 213 is guided from the winding portion of the coil to the winding fastening portion 218 of the insulator bobbin 210 to be fastened. As described above, the winding 213 is wound around the cylindrical body 214 to form a coil.

  Here, as shown in FIGS. 13 and 14, when the coil 213 is wound around the cylindrical body 214 of the insulator bobbin 210 to form a coil, a portion of the winding 213 that is located at the start of winding of the coil is Let it be a winding start portion 213a. Further, a portion of the winding 213 located on the outer periphery of the coil is a coil outer peripheral portion 213b. Further, in the winding 213, a portion that extends from the coil outer peripheral portion 213b and is inserted into the winding fastening portion 218 and is positioned at the end of winding of the coil is referred to as a winding end portion 213c.

  In the cassette coil 201 of the second prior art, as shown in FIGS. 13 and 14, the winding start portion 213a of the winding 213 and the coil outer peripheral portion 213b are adjacent to each other, and there is a risk of contact. Further, although not specifically disclosed in Patent Document 1 of the first prior art, the same applies to the coil bobbin 101 disclosed in Patent Document 1 when winding a winding to form a coil. It is thought that the part which starts winding a coil | winding and the part located in the outer periphery of a coil adjoin, and will contact.

  Here, a schematic diagram of a general coil is shown in FIG. When the winding start portion 213a, the coil outer peripheral portion 213b, and the winding end portion 213c defined in the cassette coil 201 of the second prior art are applied to a general coil, the positional relationship is as shown in FIG. In a general coil, when a current is passed through the coil, the potential difference between any contacts on the coil increases as the distance between the contacts increases. In FIG. 9, the potential difference between the points A and B at both ends of the coil is the largest.

  In particular, in the cassette coil 201 of the second prior art, since the distance between the winding start portion 213a and the coil outer peripheral portion 213b is also increased, when a high current is applied to the coil and a high voltage is applied. The potential difference between the parts also increases. The winding 213 is provided with an insulating film such as enamel, and its thickness is about 30 μm. In recent years, motors for automobiles are required to be miniaturized, but high voltage (for example, about 650 V) tends to be applied in order to improve the output. For this reason, it is important to ensure insulation between the winding start portion 213a and the coil outer peripheral portion 213b. Accordingly, when the winding start portion 213a and the coil outer peripheral portion 213b come into contact with each other, the insulation is insufficiently secured, leading to dielectric breakdown.

  In view of this, the present invention proposes a cassette coil capable of sufficiently ensuring insulation at the winding start portion and the outer peripheral portion of the coil even when a high voltage is applied, and a rotating electrical machine using the cassette coil. For the purpose.

In order to achieve the above object, the present invention has the following features.
(1) The present invention is a pair of flat plates comprising a cylindrical body wound with a winding to which an insulating film is applied to form a coil, and first and second flange portions provided at both ends of the cylindrical body. In a cassette coil having an insulator bobbin provided with a cutout portion lacking meat on the side surface of the first flange portion of the shaped hook portion, a winding start portion of a winding that is one end portion of the coil, and a winding portion of the coil An insulating member is arranged between the outer peripheral portion of the coil and the outer peripheral portion of the coil positioned on the first flange side.

(2) In the cassette coil described in (1), the present invention is characterized in that the insulating member is an insulating wall extending from a part of the first flange portion.

(3) In the cassette coil described in (1), the present invention is characterized in that the insulating member is an insulating tube that covers a winding start portion of the winding.

(4) The present invention is a pair of flat plates comprising a cylindrical body wound with a winding to which an insulating film is applied to form a coil, and first and second flange portions provided at both ends of the cylindrical body. In the rotating electrical machine having a cassette coil provided with an insulator bobbin provided with a cutout portion lacking meat on the side surface of the first flange portion of the shaped hook portion, any one of the cassettes described in (1) to (3) It has a coil.

The present invention having such features can obtain the following operations and effects.
(1) The present invention is a pair of flat plates comprising a cylindrical body wound with a winding to which an insulating film is applied to form a coil, and first and second flange portions provided at both ends of the cylindrical body. In a cassette coil having an insulator bobbin provided with a cutout portion with a lack of meat on the side surface of the first flange portion of the shaped hook portion, a winding start portion of a winding that is one end portion of the coil, and a winding portion of the coil Since the insulating member is disposed between the outer peripheral portion of the winding and the coil outer peripheral portion of the winding located on the first flange side, the insulating member is disposed in addition to the insulating property provided by the insulating film included in the winding. Since insulation is ensured, insulation at the winding start portion of the winding and the outer periphery of the coil, where the potential difference becomes large when a current is passed through the coil, is reliably ensured to prevent dielectric breakdown.

(2) In the cassette coil described in (1), since the insulating member is an insulating wall extending from a part of the first flange, in addition to the effect described in (1), The insulator bobbin is preliminarily provided with an insulating wall, and by simply winding the winding to form a coil, the insulation is ensured at the winding start portion and the coil outer peripheral portion, thereby reducing the work load and cassette. Coil productivity is improved. Further, since only the bobbin shape needs to be changed, an increase in weight can be suppressed.

(3) In the cassette coil described in (1), the insulating member is an insulating tube that covers the winding start portion of the winding. Therefore, in addition to the effect described in (1), the winding of the winding Since the insulating property can be ensured only by covering the light insulating tube at the start portion, an increase in the weight of the cassette coil can be suppressed.

(4) The present invention is a pair of flat plates comprising a cylindrical body wound with a winding to which an insulating film is applied to form a coil, and first and second flange portions provided at both ends of the cylindrical body. In the rotating electrical machine having a cassette coil provided with an insulator bobbin provided with a cutout portion lacking meat on the side surface of the first flange portion of the shaped hook portion, any one of the cassettes described in (1) to (3) Because it has a coil, in addition to the insulation by the insulation film, an insulating member is arranged to ensure more insulation, so that the insulation at the winding start portion and the outer periphery of the coil where the potential difference becomes higher when a current is passed Is reliably ensured and dielectric breakdown can be prevented.
Furthermore, the insulator bobbin is preliminarily provided with an insulating wall, and by simply winding the winding to form a coil, the insulation at the winding start portion and the outer periphery of the coil is ensured, thereby reducing the work burden. This improves the productivity of cassette coils. Further, since only the bobbin shape needs to be changed, an increase in weight can be suppressed.
Furthermore, since insulation can be ensured only by covering a lightweight insulating tube at the winding start portion of the winding, an increase in the weight of the cassette coil can be suppressed.

  Examples of the present invention will be described below.

  Example 1 will be described. FIG. 1 is an external perspective view of a cassette coil 1 according to the first embodiment. FIG. 2 is a front view of the cassette coil 1 according to the first embodiment. FIG. 3 is a view seen from the back side of the flange 15 with the flange 16 described later omitted. As shown in FIGS. 1 to 3, the cassette coil 1 is formed by winding a plurality of windings 13 around an insulator bobbin 10 to form a coil. A plurality of cassette coils 1 are arranged on the stator to constitute a motor.

  4 is a front view of the insulator bobbin 10, FIG. 5 is a top view of the insulator bobbin 10, and FIG. 6 is a side view of the insulator bobbin 10. As shown in FIGS. 4 to 6, the insulator bobbin 10 includes a cylindrical body 14 having a hollow portion 19 that is a hollow portion having a rectangular cross section, and a pair of ends formed at both ends of the cylindrical body 14. It is comprised from the flat collar part 15 and the collar part 16, etc. FIG. The insulator bobbin 10 is made of a resin such as PPS (polyphenylene sulfide) and has an insulating property. The flange portion 15 has a characteristic shape with respect to the flange portion 16 having a substantially rectangular shape. From the insulating wall 11, the cutout portion 12, the winding fastening portion 18, the cavity portion 19, the gap 20, and the like. Composed.

  As shown in FIG. 4, the meat notch portion 12 is a portion in which the meat of the collar portion 15 is cut out in a U-shape. An insulating wall 11 extends from a part of the flange 15 made of a resin such as PPS (polyphenylene sulfide) and has an insulating property into the cutout 12, and the bottom surfaces of the insulating wall 11 and the cutout 12. A gap 20 is provided between the two.

  FIG. 7 is a cross-sectional view taken along the line AA in FIG. As shown in FIG. 7, the thickness of the insulating wall 11 is made as small as possible within a range in which insulation can be ensured, and is made smaller than the thickness of the insulator bobbin 10. And it is extended in the state approached to the inner side (the collar part 16 side) of the insulator bobbin 10. FIG. Therefore, by arranging the winding start portion 13a of the winding 13 close to the insulating wall 11, the amount δ of the winding start portion 13a of the winding 13 protruding in the thickness direction of the insulator bobbin 10 can be suppressed as much as possible. Therefore, the cassette coil 1 becomes compact, and it becomes easy to insert the cassette coil 1 when inserting it into a stator core (not shown).

  Further, on the opening side of the cutout portion 12 of the insulator bobbin 10, the winding cut out in a U-shape so as to extend out of the cutout portion 12 at the facing portion of the portion where the insulating wall 11 extends. A fastening portion 18 is formed.

  Next, a method of forming a coil by winding the winding 13 around the insulator bobbin 10 provided with the insulating wall 11 will be described. First, the winding 13 is inserted from the opening side of the notched portion 12 and is inserted so as to be inserted into the gap 20 portion between the insulating wall 11 and the lower surface of the notched portion 12 as shown in FIG. As described above, in the insulator bobbin 10, since the gap 20 is provided between the insulating wall 11 and the lower surface of the cutout portion 12, the wiring of the winding 13 is guided when the winding 13 is inserted. The work burden of winding the winding 13 is reduced.

  Then, the winding 13 integrated with the two pieces is brought close to the side surface of the flange portion 15 to wind one turn around the cylindrical body 14. Then, the winding wire 13 is shifted to the flange portion 16 side and brought into contact with the already wound winding wire 13 to wind one turn around the cylindrical body 14. In this way, the winding 13 is wound while the winding 13 is gradually shifted from the flange 15 side to the flange 16 side, and the first-layer winding 13 is wound around the cylindrical body 14. Next, the second layer of winding 13 is wound around the cylindrical body 14 while shifting the winding 13 from the flange 16 side to the flange 15 in the reverse direction. Next, the third winding 13 is wound around the cylindrical body 14 while shifting the winding 13 from the flange 15 side to the flange 16 again. In this manner, a coil having a predetermined number of layers is formed by overlapping the layer of the winding 13 on the cylindrical body 14. In the uppermost layer, the winding 13 is wound while being shifted from the flange portion 16 side to the flange portion 15, and is guided and inserted into the winding fastening portion 18 of the insulator bobbin 10. As described above, the winding 13 is wound around the cylinder 14 to form a coil.

  As a feature of this embodiment, as shown in FIGS. 2 and 3, a resin insulating wall 11 is provided at a position where the winding start portion 13 a of the winding 13 is disposed. As shown in FIG. 9, when a current is passed through the coil, the potential difference between any contacts on the coil increases as the distance between the contacts increases, and between the points A and B at both ends of the coil. The potential difference becomes the largest. Since the distance between the winding start portion 13a and the coil outer peripheral portion 13b is also increased, when a high current is applied to the coil to apply a high voltage, the winding start portion 13a of the winding 13 and the coil outer peripheral portion. The potential difference from 13b increases.

  However, since the insulating wall 11 made of resin is provided in addition to the insulating film provided on the winding 13, insulation between the winding start portion 13a and the coil outer peripheral portion 13b of the winding 13 is ensured. . It should be noted that there is not much potential difference between the winding start portion 13a of the winding 13 located in the gap 20 portion and the coil on the inner peripheral side of the coil outer peripheral portion 13b even when current is passed through the coil. However, even if the gap 20 is provided between the insulating wall 11 and the lower surface of the cutout portion 12, there is no problem because the insulating film is provided on the winding 13 to ensure insulation.

  In recent years, there is a demand for miniaturization of motors for automobiles, while there is a demand for applying a high voltage (for example, about 650 V) in order to improve the output. Therefore, in addition to the insulating film (thickness of about 30 μm) provided on the winding 13 as described above, the insulating member 11 made of resin (thickness of about 1 mm) is provided, so that the insulating member is arranged in a compact manner. At the same time, the insulation between the winding start portion 13a of the winding 13 and the coil outer peripheral portion 13b is reliably ensured to maintain the output of the motor, so that these requirements can be met.

  Further, as described above, the insulating wall 11 as an insulating member extends from the flange portion 15 of the insulator bobbin 10. Therefore, for example, there is no fear that the insulating member will come off due to gravitational acceleration at the time of acceleration of a vehicle equipped with a motor having the cassette coil 1 of the present invention, vibration during driving, etc. The insulation between 13a and the coil outer peripheral portion 13b is maintained.

  Further, as shown in FIGS. 2 and 3, the insulating wall 11 is formed only in the minimum necessary range around the winding start portion 13 a of the winding 13, so that the weight of the insulator bobbin 10 can be reduced to reduce the weight of the cassette coil 1. Can be achieved.

According to the first embodiment as described above, the following effects can be obtained.
(1) In this embodiment, a pair of a cylindrical body 14 that forms a coil by winding a winding 13 to which an insulating film is applied, and a pair of flanges 15 and 16 provided at both ends of the cylindrical body 14. In a cassette coil having an insulator bobbin 10 provided with a cutout portion 12 having a lack of meat on the side surface of the flange portion 15 of the flat plate flange portions (15, 16), winding of a winding 13 which is one end portion of the coil Since the insulating wall 11 is disposed between the starting portion 13a and the outer peripheral portion of the winding portion of the coil and the outer peripheral portion 13b of the winding 13 positioned on the flange 15 side, the insulating film provided on the winding 13 is provided. Since the insulating wall 11 is disposed in addition to the insulating property by the above, the insulating property at the winding start portion 13a of the winding 13 and the outer peripheral portion 13b of the coil 13 where the potential difference increases when a current is passed through the coil is ensured. Surely secured Destruction can be prevented.

(2) In this embodiment, in the cassette coil described in (1), since the insulating member is the insulating wall 11 extending from a part of the flange 15, in addition to the effect described in (1) Since the insulator bobbin 10 is provided with the insulating wall 11 in advance and the winding 13 is wound to form the coil, the insulation at the winding start portion 13a and the coil outer peripheral portion 13b is ensured. The productivity of the cassette coil is improved by reducing the burden.

(3) In this embodiment, a pair of a cylindrical body 14 that forms a coil by winding a winding 13 to which an insulating film is applied, and a pair of flanges 15 and 16 provided at both ends of the cylindrical body 14. In the rotating electrical machine having the cassette coil including the insulator bobbin 10 provided with the cutout portion 12 lacking the meat on the side surface of the flange portion 15 of the flat plate-shaped flange portions (15, 16) of (1) or (2) Since the insulating coil 11 is disposed in addition to the insulating property of the insulating film provided in the winding 13 to secure the insulating property, the winding having a large potential difference when a current is supplied to the coil. The insulation at the winding start portion 13a and the coil outer peripheral portion 13b of the wire 13 is reliably ensured and insulation breakdown is prevented, and the insulator bobbin 10 is provided with the insulating wall 11 in advance, and the coil 13 is wound around the winding 13 It aims to reduce the work load since ensuring insulation in the winding start portion and a coil outer circumferential portion of the winding 13 by simply formed to improve the productivity of cassette coils.

  Next, Example 2 will be described. FIG. 10 is a front view of the cassette coil 2 of the second embodiment. As shown in FIG. 10, in the second embodiment, an insulating tube 17 covering the winding start portion 13a of the winding 13 is used as an insulating member. Since other configurations are the same as those in the first embodiment, the following description is omitted.

  In the cassette coil 2 of Example 2 having such a configuration, as shown in FIG. 11, the insulating tube 17 is attached from the winding start direction of the winding 13, and the winding start portion 13 a of the winding 13 is covered with the insulating tube 17. . Thus, by using the thin and lightweight insulating tube 17, it is possible to sufficiently secure the insulation at the winding start portion 13a and the coil outer peripheral portion 13b of the winding 13 while reducing the weight of the cassette coil. As the insulating tube 17, the use of a heat-shrinkable tube makes it easy to attach, and the productivity of the cassette coil 2 can be improved.

According to the second embodiment as described above, the following effects can be obtained.
(1) In this embodiment, a pair of a cylindrical body 14 that forms a coil by winding a winding 13 to which an insulating film is applied, and a pair of flanges 15 and 16 provided at both ends of the cylindrical body 14. In a cassette coil having an insulator bobbin 10 provided with a cutout portion 12 having a lack of meat on the side surface of the flange portion 15 of the flat plate flange portions (15, 16), winding of a winding 13 which is one end portion of the coil Since the insulating tube 17 is disposed between the starting portion 13a and the coil outer peripheral portion 13b of the winding 13 located on the flange 15 side, which is the outer peripheral portion of the coil winding portion, the insulating coating provided in the winding 13 Since the insulating wall 11 is disposed in addition to the insulating property by the above, the insulating property at the winding start portion 13a of the winding 13 and the outer peripheral portion 13b of the coil 13 where the potential difference increases when a current is passed through the coil is ensured. Ensured Dielectric breakdown is prevented Te.

(2) In this embodiment, in the cassette coil described in (1), since the insulating member is an insulating tube 17 covering the winding start portion of the winding 13, in addition to the effect described in (1), the winding Since insulation can be ensured only by covering the lightweight insulating tube 17 on the winding start portion 13a of the wire 13, the weight of the cassette coil can be reduced.

(3) In the present embodiment, the cylindrical body 14 that forms a coil by winding the winding wire 13 to which the insulating film is applied, and the cylindrical body out of the pair of flat plate-shaped flange portions provided at both ends of the cylindrical body 14 In a rotating electrical machine having a cassette coil provided with an insulator bobbin 10 provided with a cutout portion 12 lacking meat on a side surface of a flange portion (15, 16) provided on one end side of a body 14, (1) or (2) Since the insulating coil 11 is disposed in addition to the insulating property of the insulating film provided in the winding 13 to secure the insulating property, the winding having a large potential difference when a current is supplied to the coil. Insulation is reliably ensured at the winding start portion 13a of the wire 13 and the coil outer peripheral portion 13b to prevent dielectric breakdown, and insulation can be ensured only by covering the winding start portion 13a of the winding 13 with the lightweight insulating tube 17. This It is possible to reduce the weight of the cassette coil from.

In addition, this invention is not limited to the said embodiment, A various change is possible in the range which does not deviate from the meaning.

It is an external appearance perspective view of the cassette coil of this invention. It is a front view of the cassette coil of the present invention. It is the figure seen from the back direction of the collar part with respect to FIG. It is a front view of an insulator bobbin. It is a top view of an insulator bobbin. It is a side view of an insulator bobbin. It is AA sectional drawing of FIG. It is a figure shown about the method of winding a coil | winding around the insulator bobbin provided with the insulating wall. 1 is a schematic view of a general coil. 6 is a front view of a cassette coil according to Embodiment 2. FIG. It is a figure shown about the attachment method of an insulation tube. It is a perspective view of an insulator bobbin currently indicated by patent documents 1. It is a front view of the conventional cassette coil. It is a back perspective view of the conventional cassette coil.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cassette coil 2 Cassette coil 10 Insulator bobbin 11 Insulation wall 12 Wall notch part 13 Winding 13a Winding start part 13b Coil outer peripheral part 14 Cylindrical body 15 Gutter part 16 Gutter part 17 Insulation tube 18 Winding fastening part 19 Cavity part 20 Crevice

Claims (4)

Of a pair of flat plate-shaped flanges that are formed by winding a winding to be coated with an insulating film to form a coil and a first flange part and a second flange part provided at both ends of the cylinder body In the cassette coil having an insulator bobbin provided with a cutout portion lacking meat on the side surface of the first flange portion,
Insulation between the winding start portion of the winding, which is one end portion of the coil, and the outer peripheral portion of the winding portion of the coil and the outer peripheral portion of the winding located on the first flange side Arranging the members,
A cassette coil characterized by The cassette coil according to claim 1,
The insulating member is an insulating wall extending from a part of the first flange;
A cassette coil characterized by The cassette coil according to claim 1,
The insulating member is an insulating tube covering a winding start portion of the winding;
A cassette coil characterized by Of a pair of flat plate-shaped flanges that are formed by winding a winding to be coated with an insulating film to form a coil and a first flange part and a second flange part provided at both ends of the cylinder body In the rotating electrical machine having a cassette coil provided with an insulator bobbin provided with a cutout portion lacking meat on the side surface of the first flange portion,
Having any one of the cassette coils according to claim 1,
Rotating electric machine.

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